1. Validation of theory based transport models
in tokamak plasmas
Giovanni Tardini
PhD thesis
Supervisor: Hon. Prof. Dr. R. Wilhelm
Special thanks to: Dr. A. G. Peeters (supervisor at IPP),
Dr. G. V. Pereverzev, Dr. F. Ryter
and the ASDEX Upgrade team
G. Tardini, PhD defense, Garching, June 17th 2003

2. Outline Motivation:  Ultimately, achieve controlled nuclear fusion
 Better understanding of energy confinement in tokamak plasmas
Outline of the talk
 State of the art in transport studies and frame of this thesis
 Physics ingredients: fluid drifts, instabilities, critical gradient
 Experimental evidence and profile stiffness
 Simulation with 1D fluid models
 Conclusions
G. Tardini, PhD defense, Garching, 17th June 2003

3. Tokamak configuration
Lost by the plasma:
particles and energy
flowing radially
n toroidal windings r dq
q =
s =
n poloidal windings q dr
G. Tardini, PhD defense, Garching, 17th June 2003

4. “State of the art” of tokamak heat transport
 Particles “stick” to magnetic surfaces, Coulomb collisions cause
radial energy losses
Fourier’s law:
qj = - nj cj Tj
High temperatures for good D-T fusion rate.
 good confinement (low c) desired. Heat diffusivities:
Predicted:
i  m2/s
e  m2/s
Experimental:
i  e  1 m2/s
 Transport higher in reality + equal for ions and electrons!
Not understood? ANOMALOUS.
G. Tardini, PhD defense, Garching, 17th June 2003

5. Plasma turbulence and transport models
Anomalous transport: due to small scale microinstabilities
(  20 ri  2-5 cm) driving turbulence.
Middle 90es:
Simplified (1D) theory based models
No ad hoc free parameters to fit the data.
Affordable computing time compared to full simulations.
Easy to check dependences and stimulate experiments.
physics interpretation + reliable predictions for new experiments.
Free room for extensive modelling!
G. Tardini, PhD defense, Garching, 17th June 2003

6. Particle orbits and drifts
Particles gyrate around B, the guide centers follow the field lines.
Actually:
Drifts due to forces
Particle trapping in “magnetic mirror” configuration
G. Tardini, PhD defense, Garching, 17th June 2003

7. Growth of the Ti (ITG) driven instability
Cold plasma to cold
region: unstable!
A mechanism stabilises
the mode until a critical
Ti is reached
G. Tardini, PhD defense, Garching, 17th June 2003

8. Trapped Electron Mode (TEM)
Fast parallel e- motion: e- see also favourable curvature (high field side)
 Only fast modes (short wavelengths) !
 Small heat transport!
γ > vth/qR
But trapped e- lock parallel dynamics!!
Long wavelengths, high heat transport
G. Tardini, PhD defense, Garching, 17th June 2003

9. T driven modes and profile stiffness
G. Tardini, PhD defense, Garching, 17th June 2003

10. Experimental database
ITG dominates with strong ion heating, TEM with electron heating
70 discharges, pure NBI
7 discharges, NBI+ECH
14 discharges, pure ECH
Standard:
4 < ne [1019 m-3] < 7
PNBI = 5 MW
Ipl = 1 MA
Not shown here:
ECH power modulation
 heat pulses
 transient analysis!
Ideal to measure stiffness.
• moderate stiffness
• heat pulses well predicted!
• heat flux dependence too
0.8 < PECH [MW] < 1.6
0. < rdep < 0.33
Power scan:
1.8 < PNBI [MW] < 12.5
Current scan:
0.4 < Ipl [MA] < 1.2
Density scan:
3 < ne [1019 m-3] < 8
G. Tardini, PhD defense, Garching, 17th June 2003

11. Description of the models
IFS/PPPL (Dorland, Kotschenreuther) 1995
ITG-TEM, ci and Lcr formulas by fitting gyrokinetic (GK) simulations. ce  ci .
Limitations: s > 0.5, Ln > R/6, no electromagnetic (em) effects.
Weiland (Weiland, Nordman) 1998
ITG-TEM, fluid equations closed by taking f maxwellian in the 3rd moment (diamagnetic heat flux). Quasi linear transport. Collisionless TEM.
No em effects. Simplified q and s dependence. kri = 0.1 .
GLF23 (Waltz, Kinsey) 1997 (v1.4)
ITG-TEM, fluid closure: trial functions with free parameters fitted to GK theory. Landau damping and s-a stabilisation taken into account.
Impurities: default=dilution. Em: default=off. Spectrum with 10 values of kri.
CDBM (Itoh, Itoh) 1996
Self-sustained turbulence through current diffusion. Analytical formulas for c,
ce = ci .
G. Tardini, PhD defense, Garching, 17th June 2003

12. Experiment and modelling: Ti profile stiffness
MODELS
• Clear proportionality, Ti(.4)/Ti(.8)2
• Ratio: largely independent on scan
and boundary Ti.
• ECH lower ratio: due to Te/Ti
ITG models reproduce linear
relation; right factor.
Non-ITG: no proportionality
G. Tardini, PhD defense, Garching, 17th June 2003

13. Electron temperature: moderate stiffness
EXPERIMENT
MODELS
Ratio>2, higher for power scan!
Scattering + lower ratio for high Te.
Weak stiffness!
IFS/PPPL: wrong when electron
heating increases (NBI+ECH)
due to ce  ci
Weiland: very good!
Too optimistic for low current.
Oversimplified q-dependence
GLF23: good.
High transport for high ne
(occurs at low collisionality).
CDBM: too flat profiles!
Like ion transport.
G. Tardini, PhD defense, Garching, 17th June 2003

14. Conclusions and outlook
• Database: 91 ASDEX Upgrade discharges. Power, density, current scans, wide
T-range, ions/electrons heating  suited for transport studies!
• Core Ti  pedestal Ti, Ti (0.4)/Ti (0.8)  2 (all scans; also in JET): stiffness.
• Electrons: Te (0.4)/Te (0.8) > 2 at low Te, bends for higher Te, higher with strong
electron heating: moderate stiffness.
• “New language”: data ordered by critical gradient length rather than .
Pedestal pressure determines global confinement.
• ITG: good for ion transport! Non-ITG: no stiffness.
ITG + TEM: well predicted Te.
• ce  ci  wrong for strong electron heating. Both ion and electron turbulence
required! s and q play an important role, need accurate treating.
Open issues:
Particle transport (Dr. Angioni); momentum transport.
Simulation of Internal Transport Barriers
G. Tardini, PhD defense, Garching, 17th June 2003

15. Controlled fusion Tokamak Stellarator
G. Tardini, PhD defense, Garching, 17th June 2003

16. Stiffness or constant c
Reference profile
Constant c
Stiffness
a) Fixed boundary T,
increasing heating power
b) Constant heating power,
changing boundary T
G. Tardini, PhD defense, Garching, 17th June 2003

18. Towards a burning plasma
ITG and TEM are not dangerous for a reactor. However:
• limit energy confinement  performance
• prevent: steep T  bootstrap current  steady state operation
Margins of confinement improvement:
• high pedestal temperature, e. g. by strong plasma shaping
• peaked density profile (problematic; achievable?)
• suppressing or reducing turbulence:
s < 0 stabilises ITG and TEM
sheared plasma rotation. Too little torque in ITER’s plasma core.
G. Tardini, PhD defense, Garching, 17th June 2003

24. Energy: quantitative evaluation
G. Tardini, PhD defense, Garching, 17th June 2003

25. Electron energy: quantitative evaluation
G. Tardini, PhD defense, Garching, 17th June 2003

27. Experimental data
G. Tardini, Task Force T Meeting, Culham, May 9th 2003

29. The ASTRA code and the setup
G. Tardini, Task Force T Meeting, Culham, May 9th 2003

31. “Modern” modelling results
G. Tardini, Task Force T Meeting, Culham, May 9th 2003

32. Experiment and modelling: Ti profile stiffness
MODELS
• Clear proportionality, Ti(.4)/Ti(.8)2
• Ratio: largely independent on scan
and boundary Ti.
• ECH lower ratio: due to Te/Ti
ITG models reproduce linear
relation; right factor.
G. Tardini, PhD defense, Garching, 17th June 2003

33. Experiment and modelling: Ti profile stiffness
MODELS
• Clear proportionality, Ti(.4)/Ti(.8)2
• Ratio: largely independent on scan
and boundary Ti.
• ECH lower ratio: due to Te/Ti
ITG models reproduce linear
relation; right factor.
G. Tardini, PhD defense, Garching, 17th June 2003

34. Experiment and modelling: Ti profile stiffness
MODELS
• Clear proportionality, Ti(.4)/Ti(.8)2
• Ratio: largely independent on scan
and boundary Ti.
• ECH lower ratio: due to Te/Ti
ITG models reproduce linear
relation; right factor.
G. Tardini, PhD defense, Garching, 17th June 2003

35. Electron temperature: moderate stiffness
EXPERIMENT
MODELS
Ratio>2, higher for power scan!
Scattering + lower ratio for high Te.
Weak stiffness!
IFS/PPPL: wrong when electron
heating increases (NBI+ECH)
due to ce  ci
G. Tardini, PhD defense, Garching, 17th June 2003

36. Electron temperature: moderate stiffness
EXPERIMENT
MODELS
Ratio>2, higher for power scan!
Scattering + lower ratio for high Te.
Weak stiffness!
GLF23: good.
High transport for high ne
(occurs at low collisionality).
G. Tardini, PhD defense, Garching, 17th June 2003

37. Electron temperature: moderate stiffness
EXPERIMENT
MODELS
Ratio>2, higher for power scan!
Scattering + lower ratio for high Te.
Weak stiffness!
Weiland: very good!
Too optimistic for low current.
Oversimplified q-dependence.
G. Tardini, PhD defense, Garching, 17th June 2003

38. Tokamak configuration
Lost by the plasma:
particles and energy
flowing radially
n toroidal windings r dq
q =
s =
n poloidal windings q dr
G. Tardini, PhD defense, Garching, 17th June 2003

39. Conclusions and outlook
• Database: 91 ASDEX Upgrade discharges. Power, density, current scans, wide
T-range, ions/electrons heating  suited for transport studies!
• Core Ti  pedestal Ti, Ti (0.4)/Ti (0.8)  2 (all scans; also in JET): stiffness.
• Electrons: Te (0.4)/Te (0.8) > 2 at low Te, bends for higher Te, higher with strong
electron heating: moderate stiffness.
• “New language”: data ordered by critical gradient length rather than .
Pedestal pressure determines global confinement.
• ITG: good for ion transport! Non-ITG: no stiffness.
ITG + TEM: well predicted Te.
• ce  ci  wrong for strong electron heating. Both ion and electron turbulence
required! s and q play an important role, need accurate treating.
Open issues:
Particle transport (Dr. Angioni); momentum transport.
Simulation of Internal Transport Barriers
G. Tardini, PhD defense, Garching, 17th June 2003